System for improving cardiac function by sealing a partitioning membrane within a ventricle

ABSTRACT

Partitioning devices that may be secured and sealed within a heart chamber for separating a patient&#39;s heart chamber into a productive portion and a non-productive portion are described herein. The partitioning devices described herein may include a membrane with a plurality of inflatable elements. The membrane may include a valve disposed in a central region of the membrane with a plurality of inflation channels extending radially from the valve. These devices may be secured within the heart chamber by sealing them to the wall of the heart chamber, for example, by inflating the plurality of inflatable elements on the periphery of the device. The non-productive portion may be filled with a material, including occlusive materials. Sealing and/or filling the non-productive portion formed by the devices described herein may help prevent leakage from the non-productive region.

CROSS REFERENCE TO RELATED APPLICATIONS

This patent application claims priority as a continuation-in-part of U.S. patent application Ser. No. 13/773,235, titled “SYSTEM FOR IMPROVING CARDIAC FUNCTION BY SEALING A PARTITIONING MEMBRANE WITHIN A VENTRICLE,” filed Feb. 21, 2013, now U.S. Patent Publication No. 2013-0165735-A1, which claims priority as a continuation of U.S. patent application Ser. No. 12/422,144, titled “SYSTEM FOR IMPROVING CARDIAC FUNCTION BY SEALING A PARTITIONING MEMBRANE WITHIN A VENTRICLE,” filed Apr. 10, 2009, now U.S. Patent Publication No. 2009-0254195-A1, which is a continuation-in-part application of U.S. patent application Ser. No. 10/436,959, titled “SYSTEM FOR IMPROVING CARDIAC FUNCTION,” filed May 12, 2003, now U.S. Pat. No. 8,257,428, which claims priority as a continuation-in-part of U.S. patent application Ser. No. 09/635,511, titled “DEVICE AND METHOD FOR TREATMENT OF HOLLOW ORGANS,” filed Aug. 9, 2000, now abandoned, which claims priority to Provisional Patent Application No. 60/147,894, titled “EXPANDABLE, IMPLANTABLE DEVICE AND METHOD,” filed Aug. 9, 1999, each of which are herein incorporated by reference in their entirety.

U.S. patent application Ser. No. 12/422,144 also claims priority as a continuation-in-part application of U.S. patent application Ser. No. 11/151,164, titled “PERIPHERAL SEAL FOR A VENTRICULAR PARTITIONING DEVICE,” filed Jun. 10, 2005, now U.S. Pat. No. 7,582,051, which is herein incorporated by reference in its entirety.

This application claims priority as a continuation-in-part of U.S. patent application Ser. No. 14/448,778, titled “THERAPEUTIC METHODS AND DEVICES FOLLOWING MYOCARDIAL INFARCTION,” filed Jul. 31, 2014, now U.S. Patent Publication No. 2014-0343356-A1, which is a continuation of U.S. patent application Ser. No. 13/973,868, filed Aug. 22, 2013, titled “THERAPEUTIC METHODS AND DEVICES FOLLOWING MYOCARDIAL INFARCTION,” now U.S. Pat. No. 8,827,892, which is a continuation of U.S. patent application Ser. No. 12/129,443, filed May 29, 2008, titled “THERAPEUTIC METHODS AND DEVICES FOLLOWING MYOCARDIAL INFARCTION,” now U.S. Pat. No. 8,529,430, which is a continuation-in-part of U.S. patent application Ser. No. 11/199,633, filed Aug. 9, 2005, titled “METHOD FOR TREATING MYOCARDIAL RUPTURE,” now U.S. Patent Application Publication No. 2006-0229491-A1, now abandoned, which is a continuation-in-part of U.S. application Ser. No. 10/212,032, filed Aug. 1, 2002, titled “METHOD FOR IMPROVING CARDIAC FUNCTION,” now U.S. Pat. No. 7,279,007, each of which is herein incorporated by reference in its entirety.

U.S. patent application Ser. No. 12/129,443 also claims priority to U.S. Provisional Patent Application No. 60/985,171, filed Nov. 2, 2007, titled “ENDOCARDIAL DEVICE FOR IMPROVING CARDIAC FUNCTION,” which is herein incorporated by reference in its entirety.

INCORPORATION BY REFERENCE

All publications and patent applications mentioned in this specification are herein incorporated by reference in their entirety to the same extent as if each individual publication or patent application was specifically and individually indicated to be incorporated by reference.

FIELD

The devices, systems and methods described herein relate generally to the treatment of heart disease, particularly congestive heart failure, and more specifically, to devices, systems and methods for partitioning a patient's heart chamber and a system for delivering the treatment device.

BACKGROUND

Congestive heart failure (CHF) is characterized by a progressive enlargement of the heart, particularly the left ventricle and is a major cause of death and disability in the United States. Approximately 550,000 new cases occur annually in the U.S. alone. As the patient's heart enlarges, it cannot efficiently pump blood forward with each heartbeat. In time, the heart becomes so enlarged the heart becomes ineffective as a pump and cannot adequately supply blood to the body. Even in healthy hearts only a certain percentage of the blood in a patient's left ventricle is pumped out or ejected from the chamber during each stroke of the heart. The pumped percentage, commonly referred to as the “ejection fraction”, is typically about sixty percent for a healthy heart. A patient with congestive heart failure can have an ejection fraction of less than 40% and sometimes much lower. As a result of the low ejection fraction, a patient with congestive heart failure is fatigued, unable to perform even simple tasks requiring exertion and experiences pain and discomfort. Further, as the heart enlarges, the internal heart valves such as the mitral valve cannot adequately close. An incompetent mitral valve allows regurgitation of blood from the left ventricle back into the left atrium, further reducing the heart's ability to pump blood forwardly.

Congestive heart failure can result from a variety of conditions, including viral infections, incompetent heart valves (e.g., mitral valve), ischemic conditions in the heart wall or a combination of these conditions. Prolonged ischemia and occlusion of coronary arteries can result in myocardial tissue in the ventricular wall dying and becoming scar tissue. Once the myocardial tissue dies, it is less contractile (sometimes non-contractile) and no longer contributes to the pumping action of the heart. It is referred to as hypokinetic or akinetic. As the disease progresses, a local area of compromised myocardium may bulge out during the heart contractions, further decreasing the heart's ability to pump blood and further reducing the ejection fraction. In this instance, the heart wall is referred to as dyskinetic. The dyskinetic region of the heart wall may stretch and eventually form an aneurysmic bulge.

Patients suffering from congestive heart failure are commonly grouped into four classes, Classes I, II, III and IV. In the early stages, Classes I and II, drug therapy is presently the most common treatment. Drug therapy typically treats the symptoms of the disease and may slow the progression of the disease, but it cannot cure the disease. Presently, the only permanent treatment for congestive heart disease is heart transplantation, but heart transplant procedures are very risky, extremely invasive and expensive and are performed on a small percentage of patients. Many patients do not qualify for heart transplant for failure to meet any one of a number of qualifying criteria, and, furthermore, there are not enough hearts available for transplant to meet the needs of CHF patients who do qualify.

Substantial effort has been made to find alternative treatments for congestive heart disease. For example, surgical procedures have been developed to dissect and remove weakened portions of the ventricular wall in order to reduce heart volume. This procedure is highly invasive, risky and expensive and is commonly only done in conjunction with other procedures (such as heart valve replacement or coronary artery by-pass graft). Additionally, the surgical treatment is usually only offered to Class III and IV patients and, accordingly, is not an option for most patients facing ineffective drug treatment. Finally, if the procedure fails, emergency heart transplant is the only presently available option.

Mechanical assist devices have been developed as intermediate procedures for treating congestive heart disease. Such devices include left ventricular assist devices and total artificial hearts. A left ventricular assist device includes a mechanical pump for increasing blood flow from the left ventricle into the aorta. Total artificial heart devices, such as the Jarvik heart, are usually used only as temporary measures while a patient awaits a donor heart for transplant.

Recently, improvements have been made in treating patients with CHF by implanting pacing leads in both sides of the heart in order to coordinate the contraction of both ventricles of the heart. This technique has been shown to improve hemodynamic performance and can result in increased ejection fraction from the right ventricle to the patient's lungs and the ejection fraction from the left ventricle to the patient's aorta. While this procedure has been found to be successful in providing some relief from CHF symptoms and slowed the progression of the disease, it has not been able to stop the disease and is only indicated in patients with ventricular dissynchrony.

Other efforts to treat CHF include the use of an elastic support, such as an artificial elastic sock, placed around the heart to prevent further deleterious remodeling.

Described herein are ventricular partitioning devices that address many of the problems associated with devices that reduce heart volume or modify cardiac contraction. In particular, the devices, systems and methods described herein may reduce volume in a ventricle in a way that avoids leakage or the release of potentially thrombogenic materials.

Further, the present invention relates generally to the field of treating heart disease, particularly preventing remodeling following myocardial infarction.

When normal blood supply to myocardium is stopped due to occluded coronary artery, affected heart muscle cells get severely damaged and/or die, i.e., the myocardium (heart muscle) becomes infracted. This may result in permanent damage to the heart, reduced effectiveness of the heart pumping ability, and is frequently followed by enlargement of the heart and symptoms of heart failure.

An acute myocardial infarction (AMI) may lead to severe myocardial damage resulting in myocardial rupture. Mortality rates for myocardial rupture are extremely high unless early diagnosis and surgical intervention are provided rapidly. Cardiac rupture is a medical emergency. The overall risk of death depends on the speed of the treatment provided, therefore fast and relatively easy treatment option is needed.

Myocardial regions affected by infarction may change size and shape, i.e., remodels, and in many cases non-affected myocardium remodels as well. The infracted region expands due to the forces produced by the viable myocardium. Whether these changes become permanent and progress to involve infracted border zones and remote non-infarcted myocardium may depend on multiple factors, including infarct size, promptness of reperfusion, post-infarction therapy, etc. However, even following small infarction, many patients treated with the state-of-the-art therapies show some degree of regional and subsequent global ventricular shape changes and enlargement. Early infarct expansion results from degradation of the extracellular collagen framework that normally provides myocardial cells coupling and serves to optimize and evenly distribute force development within the ventricular walls. In the absence of extracellular matrix, the infracted region becomes elongated, may increase in radius of curvature, and may start thinning which involves the process of myocyte “slippage”. These changes may cause an immediate increase in the radius of curvature of adjacent border zone myocardium also result in the increase in the border zone wall stress. The cumulative chronic effect of these changes is the stress elevation within the ventricular walls, even in the non-infarcted myocardium. Increased stress, in turn, leads to progressive ventricular dilatation, distortion of ventricular shape, mural hypertrophy and more myocardial stress increase, ultimately causing deterioration of the heart pump function. FIG. 38 shows a summary flowchart illustrating the effects of acute myocardial infarction. Once myocardial infarction has occurred, myocardial cells undergo cell death resulting in expansion of the damaged or infarcted region. Among other effects, myocardial infarction then results in ventricle dilation and remodeling.

Therapies for treatment of disorders resulting from cardiac remodeling (or complications of remodeling) are highly invasive, risky and expensive, and are commonly only done in conjunction with other procedures (such as heart valve replacement or coronary artery by-pass graft). These procedures are usually done several months or even years after the myocardial infarction when hear is already dilated and functioning poorly. Thus, it would be beneficial to treat myocardial infarction prior to remodeling.

Described herein are methods and devices which may be used for the immediate and early treatment of myocardial infarction. Cardiac rupture post myocardial infarction needs to be treated immediately. The early and rapid appearance of infarct and border zone lengthening and early infarct expansion may be prevented by the early treatments described herein to prevent or attenuate initial myocardial infarct region expansion early after myocardial infarction. These methods and implants may provide an immediate mechanical effect to prevent or attenuate ventricular remodeling, and may also be used in conjunction with therapeutic agents and/or cells to the cardiac endothelium.

SUMMARY OF THE DISCLOSURE

The present invention is directed to ventricular partitioning devices, systems and methods of employing ventricular partitioning devices in the treatment of a patient with heart disease and particularly congestive heart failure (CHF). Specifically, the devices described herein partition a chamber of the patient's heart into a main productive portion and a secondary non-productive portion, and form a seal between the two portions. In some variations, the devices include a separate chamber that is configured to fit within the non-productive portion. Partitioning reduces the total volume of the heart chamber, reduces the stress applied to weakened tissue of the patient's heart wall and, as a result, improves the ejection fraction thereof. Moreover, the expansive nature of the device improves the diastolic function of the patient's heart.

In general, the partitioning devices described herein have a reinforced partitioning component with a concave, pressure receiving surface which defines in part the main productive portion of the partitioned heart chamber when secured within the patient's heart chamber. The reinforced partitioning component may include a flexible membrane that forms the pressure receiving surface. The partitioning component may be reinforced by a radially expandable frame component formed of a plurality of ribs. The ribs of the expandable frame may have secured distal ends, which are preferably secured to a central hub, and free proximal ends. The distal ends of the ribs may be secured to the central hub to facilitate radial self expansion of the free proximal ends of the ribs away from a centerline axis. The distal ends of the ribs may be pivotally mounted to the hub and biased outwardly or fixed to the hub. The ribs are preferably formed of material such as superelastic NiTi alloy which allows for compressing the free proximal ends of the ribs toward a centerline axis into a contracted configuration for delivery and self-expansion when released for deployment to an expanded configuration when released within the patient's heart chamber.

The free ends of the ribs may be configured to engage and preferably penetrate the tissue lining the heart chamber to be partitioned so as to secure the peripheral edge of the partitioning component to the heart wall and fix the partitioning component within the chamber so as to partition the chamber in a desired manner. The tissue penetrating proximal tips may be configured to penetrate the tissue lining at an angle approximately perpendicular to a center line axis of the partitioning device. The tissue penetrating proximal tips of the ribs may be provided with barbs, hooks and the like which prevent withdrawal from the tips from the heart wall.

The portioning devices described herein may also include a sealing element (or sealing elements) configured to seal the device (which may be separately secured to the heart wall) to the heart wall. For example, the device may include an expansive member such as one or more strands, swellable pads, inflatable balloons, or the like, that extend between at least one pair of adjacent ribs at or close to the outer edge or periphery of the membrane to seal the membrane to the heart wall. For example, the sealing element may exert pressure to the flexible membrane periphery when the partitioning device is in an expanded configuration to ensure an adequate seal between the membrane periphery and the lining of the heart wall. In one embodiment, a single strand or strands extend around essentially the entire periphery of the membrane so that the flexible periphery of the membrane between each pair of ribs is effectively sealed against the heart wall. The expansive strand or strands may be formed of material which is stiffer than the flexible, unsupported material of the membrane to provide an outward expansive force or thrust to prevent formation of inwardly directed folds or wrinkles when the ribs of the partitioning device are in at least a partially contracted configuration. Suitable strand or strands are formed of material such as polypropylene suture or superelastic NiTi alloy wires. Such strands may typically be about 0.005 to about 0.03 inch (0.13-0.76 mm) in diameter to provide the requisite outward expansive force when placed in a circular position such as around the periphery of the membrane in less than completely expanded configuration.

In another embodiment expandable pads are provided between each adjacent pair of ribs which are configured to swell upon contact with body fluids to provide an outward expansive force or thrust, as above, to prevent formation of inwardly directed folds or wrinkles when the ribs of the partitioning device are in at least a partially contracted configuration. Preferably the pads are formed of expansive hydrophilic foam. Suitable swellable materials includable collagen, gelatin, polylactic acid, polyglycolic acid, copolymers of polylactic acid and polyglycolic acid, polycaprolactone, mixtures and copolymers thereof. Other suitable swellable bioresorbable polymeric materials may be employed. The expandable pads may be formed so as to deliver a variety of therapeutic or diagnostic agents.

In some variations, the ribs in their expanded configuration typically angle outwardly from the hub and the free proximal ends curve outwardly so that the membrane secured to the ribs of the expanded frame forms a trumpet-shaped, pressure receiving surface.

The partitioning membrane in the expanded configuration may have radial dimensions from about 10 to about 160 mm, preferably about 25 to about 50 mm, as measured from the center line axis. The membrane is preferably formed of flexible material or fabric such as expanded polytetrafluoroethylene (ePTFE).

The partitioning device may be designed to be oversized with respect to the chamber in which it is to be deployed so that the ribs of the device apply an outward force against the chamber wall. When the partitioning device is collapsed for delivery, the outwardly biased strand or strands ensures that there are no inwardly directed folds or wrinkles and that none are formed when the partitioning device is expanded for deployment within the heart chamber.

In one partitioning device design, the free ends of the expansive strand or strands may be secured together or to the partitioning device. Alternatively, in another device design, the expansive strand or strands may be long enough so that one or both free ends thereof extend out of the patient to facilitate collapse and retrieval of the partitioning device. Pulling on the free ends of the strand extending out of the patient closes the expanded portion i.e., the ribs and membrane, of the partitioning device to collapse of the device and such pulling can pull the collapsed partitioning device into the inner lumen of a guide catheter or other collecting device

The reinforced partitioning component may include a supporting component or stem which has a length configured to extend distally to the heart wall surface to support the partitioning device within the heart chamber. For example, the supporting component may have a plurality of pods or feet, preferably at least three, which distribute the force of the partitioning device about a region of the ventricular wall surface to avoid immediate or long term damage to the tissue of the heart wall, particularly compromised or necrotic tissue such as tissue of a myocardial infarct (MI) and the like. Pods of the support component may extend radially and preferably be interconnected by struts or planes which help distribute the force over an expanded area of the ventricular surface.

Any of the partitioning devices described herein may be delivered percutaneously or intraoperatively. Thus, methods of delivery and devices for delivering them are also described herein. For example, one delivery catheter which may be used has an elongated shaft, a releasable securing device on the distal end of the shaft for holding the partitioning device on the distal end and an expandable member such as an inflatable balloon on a distal portion of the shaft proximal to the distal end to press the interior of the recess formed by the pressure receiving surface to ensure that the tissue penetrating tips or elements on the periphery of the partitioning device penetrate sufficiently into the heart wall to hold the partitioning device in a desired position to effectively partition the heart chamber. For example, one variation of a suitable delivery device is described in patent application Ser. No. 10/913,608, titled “VENTRICULAR PARTITIONING DEVICE,” filed Aug. 5, 2004, now U.S. Patent Publication No. 2006-0030881-A1, now abandoned and assigned to the present assignee.

For example, described herein are devices for partitioning a patient's ventricle into a productive portion and a non-productive portion, the device comprising: a membrane and a membrane support frame sized to span the patient's ventricle, wherein the membrane support frame comprises a plurality of support struts configured to have a collapsed and an expanded configuration; at least one securing element extending from the periphery of the membrane; and an inflatable sealing element on a peripheral portion of the membrane configured to seal the peripheral portion of the membrane to a wall of the ventricle.

In general, the inflatable sealing element includes swellable sealing elements. A swellable sealing element typically inflates from a smaller profile to a larger (swelled or inflated) profile. Any of the inflatable sealing elements described herein may be considered expansive members that expand in order to secure and/or seal the membrane of the devices against a wall of a heart chamber. In some variations, the inflatable sealing element extends annularly around the perimeter of the membrane. For example, the inflatable sealing element may be a plurality of inflatable sealing elements extending between the support struts.

The membrane support frame may be configured to form a recess in the expanded configuration.

Any of the devices described herein may also include a valve configured to allow access to the non-productive portion when the device is deployed in the subject's ventricle. In some variations, the valve comprises a one-way valve.

The membrane may be formed at least in part of a flexible material.

The devices described herein may also include an inflation valve fluidly connected to the inflatable sealing element.

The inflatable sealing element may be formed of any appropriate material, in particular, the inflatable sealing element may be formed of a bioabsorbable material. In some variations, the bioabsorbable material is selected from the group consisting of collagen, gelatin, polylactic acid, polyglycolic acid, copolymers of polylactic acid and polyglycolic acid, polycaprolactone, mixtures and copolymers thereof.

Any of the partitioning devices described herein may also include a central hub to which the membrane support frame is secured, and/or a stem with a non-traumatic distal tip configured to engage a region of the chamber defining in part the non-productive portion thereof. The securing elements may be anchors, and may be tissue penetrating. For example, the securing elements may have a tissue penetrating tip. The securing element(s) may be outwardly curved.

In some variations, the partitioning device may also include one or more containers secured to the device that may be filled once the device is inserted into the ventricle. For example, the device may include a container secured to the device and configured to be positioned within the non-productive portion of the subject's ventricle when the device is deployed in the subject's ventricle. The container may be a bag having flexible walls, or it may have rigid or semi-flexible walls. The container may be collapsed or foldable. In some variations the membrane connected to the support frame forms a wall or portion of the container. Thus, the container may extend from the membrane and/or support frame distally, so that it may be positioned within the non-productive portion of the ventricle when the device is deployed. Portions of the device may be contained within the container. For example, a stem portion, a foot portion, etc. may be positioned within the container. The container may be expandable. For example, the container may be a flexible or stretchable fabric. The container may be configured to hold a fluid or solid. Thus, in some variations the container is configured to be fluid-tight. In some variations the container may be filled with a fluid such as saline, blood, etc. In other variations, the container may be permeable or semi-permeable.

Also described herein are methods for treating a patient, including a patient having a heart disorder, or at risk for a heart disorder. The method may include the steps of: percutaneously advancing a contracted partitioning device into a patient's ventricle; expanding the partitioning device into a deployed configuration within the ventricle; and sealing the expanded partitioning component to the wall of the ventricle to separate the ventricle into a productive portion and a non-productive portion to prevent communication between the productive portion and non-productive portions.

The method may also include the step of filling the non-productive portion. For example, the non-productive portion may be filled with a bio-resorbable filler such as polylactic acid, polyglycolic acid, polycaprolactone and copolymers and blends. In some variations, the filler is an occlusive material such as a coil (e.g., vasoocclusive coil) or the like. Fillers may be suitably supplied in a suitable solvent such as dimethylsulfoxide (DMSO). Other materials which accelerate tissue growth or thrombus may be deployed in the non-productive portion, as well as non-reactive fillers.

The sealing step may include expanding a sealing element against the ventricle wall from the partitioning device. The sealing step may include the step of biasing a membrane toward the heart wall with the sealing element. For example, the expanding step may include inflating the sealing element. In some variations, the sealing element may be actively expanded (e.g., by applying air or other fluids), or passively expanded (e.g., by allowing swelling).

Also described herein are methods of treating a patient comprising the steps of: percutaneously advancing a contracted partitioning device into a patient's ventricle; expanding the partitioning device into a deployed configuration within the ventricle; securing the expanded partitioning device to the ventricle wall to separate the ventricle into a productive portion and a non-productive portion; and adding a filling material to the non-productive portion.

In some variations, the step of adding a filling material includes applying material through a valve on the partitioning device. The valve may be a one-way valve. The material may be applied through a channel in the applicator. For example, the applicator may engage with a valve on or through the device. In some variations, the device is passively filled. For example, one or more valves may allow the entry of blood flow behind the device, but may prevent the blood (or any thrombosis) from exiting the non-productive space behind the valve. Thus the step of adding the filing material may include passively allowing a blood to fill a compartment portion of the partitioning device through a valve on the device.

In some variations, the step of adding a filling material includes applying a filling material into a compartment portion of the partitioning device through a valve. As mentioned above the compartment may be filled with any appropriate filling material, including fluids, solids, or some combination thereof. For example, the step of adding a filling material may include applying one or more coils to the non-productive portion. The coils (e.g., vasooccluisve coils) or other filling material may be added to a compartment portion of the partitioning device. The step of adding the filing material may comprise applying saline to a compartment portion of the partitioning device.

Also described herein are applicators for applying a partitioning device of a ventricle of a patient's heart. An applicator may include: an elongated shaft which has proximal and distal ends; an deploying inflation port on the proximal end of the shaft and an inner lumen in fluid communication with the port; a releasable securing element on the distal end of the elongated shaft configured to secure and release the partitioning device; an inflatable member on a distal portion of the elongated shaft having an interior in fluid communication with the deploying inflation port, wherein the inflatable member is configured to expand a membrane of the partitioning device; and a filling interface near the distal end of the elongated shaft, wherein the filling interface is configured to apply a filling material through a valve on the partitioning device.

One particular variation of the devices for partitioning a patient's ventricle into a product and non-productive portion includes an inflatable sealing element that is a balloon element. For example, described herein are devices for partitioning a patient's ventricle into a productive portion and a non-productive portion. Such devices may include a membrane and a membrane support frame sized to span the patient's ventricle, wherein the membrane support frame comprises a plurality of support struts configured to have a collapsed and an expanded configuration, at least one securing element extending from the periphery of the membrane, and an inflatable sealing balloon element on a peripheral portion of the membrane configured to seal the peripheral portion of the membrane to a wall of the ventricle.

As mentioned above, the inflatable sealing balloon element may extend substantially around the perimeter of the membrane. In some variations, the partitioning devices include a plurality of inflatable sealing balloon elements extending between support struts.

A partitioning device may also include an inflation port configured to connect the inflatable sealing balloon element to a channel on a delivery device. The devices may also include an inflation valve fluidly connected to the inflatable sealing element.

As mentioned above, the securing element(s) of the partitioning device may have a tissue penetrating tip.

These partitioning devices may also include a container secured to the device and configured to be positioned within the non-productive portion of the subject's ventricle when the device is deployed in the patient's ventricle.

Also described herein are devices for partitioning a ventricle of a patient's heart into a productive portion and a non-productive portion that include: a membrane and a membrane support frame, the membrane and the membrane support frame sized to span the patient's ventricle, wherein the membrane and the membrane support frame are configured to have a collapsed configuration and an expanded configuration; at least one securing element on a peripheral portion of the membrane configured to secure the membrane to a wall of the ventricle; and a container secured to the device and configured to be positioned within the non-productive portion of the subject's ventricle when the device is deployed in the subject's ventricle. The container may be secured to the membrane. In some variations, the membrane forms a wall or portion of the container. The container may extend from a peripheral portion of the membrane.

The container may be configured to substantially conform to the ventricular wall. For example, the container may be fillable so that it contacts all or a portion of the ventricle wall in the non-productive portion of the ventricle. In some variations, the container is configured as a bag.

As mentioned above, the container may be expandable, or it may have a fixed volume. The container may be made of a flexible material. In some variations, the container comprises one or more rigid walls. The container may be permeable or impermeable. In general, the container may be fillable. For example, the container may be configured to be filled with a fluid. In some variations, the container is configured to be filled with one or more coils or other occlusive members. The devices described herein may include a valve providing access into the container. For example, the valve may be configured to permit filling, but not emptying of the container. Thus, in one variation the valve is a one-way valve configured to allow the container to passively fill with blood from the ventricle. In some variations, the container may be configured so that the valve can permit emptying.

Any of the features of the partitioning devices described herein may be included as part of the portioning devices including a container. For example, the devices may include a central hub, a stem, a foot (e.g., an atraumatic foot), or the like. In some variations the device may be configured so that one or more of these elements is contained within the container.

Also described herein are methods of treating a patient comprising: percutaneously advancing a contracted partitioning device into a patient's ventricle; expanding the partitioning device into a deployed configuration within the ventricle; sealing the expanded partitioning component to the wall of the ventricle to separate the ventricle into a productive portion and a non-productive portion to prevent communication between the productive portion and non-productive portions; and filling a container portion of the implant that is secured within the non-productive portion of the ventricle.

The step of filling may comprise filling the container portion with an occlusive device, or with some other solid and/or liquid material, e.g., saline.

Also described herein are applicators for applying a partitioning device to a ventricle of a patient's heart, the applicator comprising: an elongated shaft which has proximal and distal ends; a deploying inflation port and a sealing inflation port on the proximal end of the shaft; an inner lumen in fluid communication with at least one of the ports; a releasable securing element on the distal end of the elongated shaft configured to secure and release the partitioning device; an inflatable member on a distal portion of the elongated shaft having an interior in fluid communication with the deploying inflation port; and a sealing inflation interface near the distal end of the elongated shaft in fluid communication with the sealing inflation port, wherein the sealing inflation interface is configured to couple to an inflatable sealing element of the partitioning device.

Other variations of partitioning devices having one or more chambers are also described herein. For example, described herein are ventricular chamber volume reduction systems, comprising: a container body deliverable into a portion of a ventricular chamber, and wherein the container body is expandable from a first shape to a second shape when delivered into the ventricular chamber, the container body having a tissue surface in contact with a wall of the ventricular chamber and an exposed surface facing into the volume of the ventricular chamber not occupied by the container body, and wherein the exposed surface substantially spans across the ventricular chamber, wherein the second shape of the container body occupies substantially all of the space in the ventricular chamber between the wall of the portion of the ventricular chamber and the exposed surface, thereby reducing ventricular volume exposed to a flow of blood. In some variations, these devices also include a partition, wherein the partition is positioned on the side of the container adjacent to the exposed surface.

As mentioned above, the second shape of the container body may occupy substantially all of the space in the ventricular chamber between the wall of the portion of the ventricular chamber and the exposed surface. For example, when the device is filled with material, one or more walls of the device may contact the sides of the ventricle in the non-productive portion of the ventricle.

The container body may include an attachment device that affixes the tissue surface to the wall of the ventricular chamber. For example, the container body may include one or more anchors, hooks, barbs or the like. In some variations, the container body may include one or more struts or arms that apply pressure to secure the tissue surface to a wall of the ventricular chamber. In some variations the chamber body may be sealed against the wall of the ventricular chamber by expanding or inflating an inflatable member, as described above. The inflatable member may be present with the container. In some variations, the expandable member is present on the outside of the container. The container may also be expandable and/or inflatable.

A partitioning device embodying features of the invention may be relatively easy to install and may be a substantially improved treatment of a diseased heart. A more normal diastolic and systolic movement of a patient's diseased heart may thus be achieved. Concomitantly, an increase in the ejection fraction of the patient's heart chamber can be obtained.

Described herein are methods, devices and systems for treatment the heart following myocardial infarction. In general, these methods typically require the application of a treatment device that supports and/or isolates the infracted region of the heart within about 72 hours of the ischemic event. These methods may be used, for example, to treat a portion of the left ventricle that is affected by myocardial infarction.

In general, a treatment device may be a support device that provides mechanical support to the region of the heart affected by the myocardial infarction, and/or a partitioning device (e.g., including a membrane) that at least partially isolates the region of the heart chamber affected by the myocardial infarction and/or cardiac rupture. In some variations the treatment device is both a support device and a partitioning device.

For example, described herein is a method of preventing cardiac rupture following myocardial infarction comprising delivering a device to a heart chamber exhibiting myocardial infarction within 72 hours of myocardial infarction (wherein the device comprises a reinforced membrane) and deploying the device in the chamber adjacent the region of the chamber wall exhibiting myocardial infarction.

The method may also include the step of identifying the region of the heart chamber exhibiting myocardial infarction. Any appropriate method of identifying the region of the heart chamber exhibiting the myocardial infarction may be used, including visual inspection, electrical inspection, imaging by echocardiography, magnetic resonance or computerized tomography, or the like. For example, electrical inspection may be performed by the use of ECG measurements and analysis, or the use of electrodes on or around the heart tissue. Visual inspection may be done using direct (light) visualization, or by labeling for markers or reactivity. For example, ultrasound may be used to identify region of the heart affected by the myocardial infarction.

As mentioned, a treatment device may include a membrane (e.g., a reinforced membrane). The membrane may be non-porous or porous to allow fluid (including blood) exchange across it. The device may include an expandable frame. The membrane may be attached or connected to the expandable frame. The expandable frame may be formed of an elastic or superelastic material, such as a shape memory material (e.g., Nitinol™, or other superelastic materials). The expandable frame may be formed of a plurality of struts that extend from a hub. The device may also include a foot (e.g., a non-traumatic foot) for contacting the wall of the chamber. In some variations the device is configured so that only minimal (if any) space is partitioned.

The step of delivering the device may include delivering the device in a collapsed configuration. In general, the delivery step may include the step of delivering the device in a collapsed state through a catheter or other inserter. Thus, the device may be held in a first, collapsed or delivery, configuration and may be deployed by expanding into the deployed configuration. The device may be self-expanding, or it may be expanded using a mechanical expander such as a balloon or other structure. Thus, the step of delivering the device may include using a delivery catheter.

When a device is used to treat the heart, the device may be sealed about the periphery of the membrane of the device against the chamber wall of the heart being treated. Any appropriate sealing technique may be used. For example, the device may include a seal region, e.g., an expandable, inflatable, or other region. Examples of devices including a seal are provided herein, and may also be found, for example, in US Patent Publication No. 2006/0281965, herein incorporated by reference in its entirety.

The step of deploying the device may therefore also include isolating the region of the chamber wall exhibiting myocardial infarction from the rest of the chamber.

The step of deploying the device may also comprise partitioning the heart chamber into a main productive portion and a secondary non-productive portion, with the region of the chamber exhibiting myocardial infarction or cardiac rupture forming a part of the secondary non-productive portion.

In some variations the treatment device may include anchors or attachments for securing the device to the wall of the heart chamber. For example, the device may include hooks and/or barbs on the membrane and/or expandable frame. Thus, the methods of preventing remodeling due to myocardial infarction may include the step of securing or anchoring the device to the heart wall. In particular, the device may be anchored or secured to the heart wall over the region of myocardial infarction.

One or more therapeutic agents may also be delivered to the heart tissue (e.g., the heart wall) from the device. For example, the device may be coated or impregnated with a therapeutic material. In some variations a therapeutic material is added to the heart chamber after the device is inserted, for example in the space between the device and the heart wall.

Also described herein are methods of preventing cardiac remodeling following myocardial infarction comprising the step of: delivering a device to a left ventricle within 72 hours of myocardial infarction (wherein the device comprises a reinforced membrane) and deploying the device in the left ventricle adjacent a region of the left ventricle exhibiting myocardial infarction.

Also described herein are methods of preventing cardiac remodeling following myocardial infarction. These methods may include delivering a support device to a heart chamber exhibiting myocardial infarction within 72 hours of myocardial infarction (wherein the support device comprises a an expandable frame) and deploying the support device in the chamber adjacent the region of the chamber wall exhibiting myocardial infarction. As mentioned, the method may also include the step of identifying the region of the heart chamber exhibiting myocardial infarction.

The step of delivering the support device may comprise delivering the support device in a collapsed configuration. The support device may be any of the treatment devices described herein; for example, the support devices may be a device having a plurality of struts extending from a central hub. The support device may include a reinforced membrane (which may be impermeable, or permeable, or semi-permeable). The support device may include a foot (e.g., a non-traumatic foot), or a non-traumatic hub.

The step of deploying the support device may include securing the support device to the wall of the chamber. In general, the treatment devices described herein may dynamically flex as the wall of the chamber moves. For example, the support device may be made of a material (e.g., a shape memory alloy) that supports the wall, and flexes as the heart beats.

These and other advantages of the invention will become more apparent from the following detailed description of the invention and the accompanying exemplary drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an elevational view of a partitioning device embodying features of the invention in an expanded configuration.

FIG. 2 is a plan view of the partitioning device shown in FIG. 1 illustrating the upper surface of the device.

FIG. 3 is bottom view of the partitioning device shown in FIG. 1.

FIG. 4 is a perspective view of the non-traumatic tip of the distally extending stem of the device shown in FIG. 1.

FIG. 5 is a partial cross-sectional view of the hub of the partitioning device shown in FIG. 2 taken along the lines 5-5.

FIG. 6 is a transverse cross sectional view of the hub shown in FIG. 5 taken along the lines 6-6.

FIG. 7 is a longitudinal view, partially in section of a reinforcing rib and membrane at the periphery of the partitioning device shown in FIG. 1.

FIG. 8 is a schematic elevational view, partially in section, of a delivery system with the partitioning device shown in FIGS. 1 and 2 mounted thereon.

FIG. 9 is a transverse cross-sectional view of the delivery system shown in FIG. 8 taken along the lines 9-9.

FIG. 10 is an elevational view, partially in section, of the hub shown in FIG. 5 being secured to the helical coil of the delivery system shown in FIG. 8.

FIGS. 11A, 11B, 11C, 11D and 11E are schematic views of a patient's left ventricular chamber illustrating the deployment of the partitioning device shown in FIGS. 1 and 2 with the delivery system shown in FIG. 8 to partition a patient's heart chamber (left ventricle) into a primary productive portion and a secondary, non-productive portion.

FIG. 12 is a schematic plan view of the deployed device shown in FIG. 11E within a patient's heart chamber.

FIG. 13 is a schematic plan view of the partitioning device shown in FIG. 1 without the expansive strand after deployment within a patient's heart chamber.

FIG. 14 is a partial schematic view of the partitioning device shown in FIGS. 1 and 2 in a contracted configuration resulting from pulling the free ends of the expansive strand at the periphery of the reinforced membrane.

FIG. 15 is a schematic view of the contracted device shown in FIG. 14 being pulled into an expanded distal end of a receiving catheter to facilitate withdrawal of the partitioning device into a receiving catheter.

FIG. 16 is a schematic view of the contracted device shown in FIG. 14 pulled further into the inner lumen of the receiving catheter.

FIG. 17 is a perspective view of the bottom of an alternative partitioning device which has swellable pads disposed between adjacent ribs to press the membrane between the ribs against the heart wall.

FIG. 18 is a cross-sectional view of a swellable pad disposed between two membrane layers secured to the ribs of the partitioning device.

FIG. 19A is a cross-sectional side view of a human heart with the catheter inserted therein.

FIGS. 19B, 19C, 19D, 19E, 19F, 19G, 19H, 191, 19J and 19K are cross-sectional side views of the human heart illustrating installation (FIGS. 19B-19E), removal (FIGS. 19E-19H), and subsequent final installation (FIGS. 19I-19K) of the cardiac device.

FIG. 20A is a perspective view of a cardiac device according to a further embodiment of the invention.

FIG. 20B is a cross-sectional side view of the cardiac device of FIG. 20A.

FIG. 20C is a cross-sectional side view of the human heart with the cardiac device of FIG. 20A installed.

FIGS. 21A, 21B and 21C illustrate a variation of a partitioning device having an inflatable seal. FIG. 21A shows the device in the collapsed (delivery) configuration, while FIG. 21B shows a partially expanded view. FIG. 21C shows a partial cut-away view of the device of FIGS. 21A and 21B.

FIGS. 22A and 22B show a partitioning device having a container configured to be positioned within the non-productive portion of a ventricle when the device is delivered to a ventricular chamber, as illustrated in FIG. 22B.

FIGS. 23A and 23B, respectively, show a bottom and side perspective view of another variation of a partitioning device including a container portion.

FIGS. 24A and 24B show side perspective and top views, respectively of another variation of a partitioning device having both a container and a valved port for filling the container.

FIGS. 25A and 25B illustrate operation of a partitioning device similar to that shown in FIGS. 24A and 24B.

FIG. 26 shows a delivery catheter for a partitioning device having a valved container.

FIG. 27 illustrates operation of a delivery catheter similar to the delivery catheter shown in FIG. 26.

FIG. 28 illustrates one method of implanting a partitioning device as described herein.

FIGS. 29A and 29B illustrate another variation of a method of using a partitioning implant.

FIG. 29C illustrates an alternative method of operating a portioning device similar to the version shown in FIG. 29B.

FIGS. 30A and 30B show another variation of a partitioning device including an inflatable sealing element.

FIGS. 30C and 30D illustrate operation of the device shown in FIGS. 30A and 30B.

FIGS. 31A and 31B show another variation of a partitioning device including an inflatable element that may be used to expand the device.

FIG. 32A is a schematic view of a patient's heart having a myocardial infarct.

FIG. 32B is a schematic view of the patient's heart of FIG. 32A with a ventricular septal defect resulting from a rupture in the heart wall.

FIG. 32C is a schematic view of the patient's heart of FIG. 32B after treatment following rupture of the heart wall.

FIG. 32D is a schematic view of the patient's heart after immediate early treatment, as described herein.

FIG. 33A is a schematic view of a patient's heart exhibiting a myocardial infarct with free wall rupture of the left ventricular chamber.

FIG. 33B is a schematic view of the patient's heart of FIG. 33A with a left ventricular chamber tamponade.

FIG. 33C is a schematic view of the patient's heart of FIG. 33B after treatment following development of tamponade.

FIG. 34 is a schematic view of the patient's heart after treatment according to a method of the present invention.

FIG. 35A illustrate one variation of an implant which may be used with the present invention.

FIG. 35B shows another variation of an implant which may be used with the present invention.

FIG. 35C is a schematic view of a heart in which the implant of FIG. 35A has been implanted.

FIG. 36A illustrates another variation of an implant which may be used with the present invention.

FIG. 36B is a schematic view of a heart in which the implant of FIG. 36A has been implanted.

FIGS. 37A and 37B show another variation of an implant which may be used following acute myocardial infarction.

FIGS. 37C and 37D illustrate a delivery system for delivering an implant such as the implant of FIGS. 37A and 37B.

FIG. 38 schematically illustrates the effects of myocardial infarction.

FIGS. 39A and 39B are schematic illustrations of a heart in which the implant has been applied.

DETAILED DESCRIPTION

Partitioning devices, systems including partitioning devices, and methods of using partitioning devices to treat subjects are described herein. In general, the partitioning devices described herein are configured to partition a heart chamber, and in particular a ventricular chamber, into a productive portion and a non-productive portion. These partitioning devices may be delivered in a collapsed configuration (e.g., percutaneously), and expanded within the ventricle and secured in position within the ventricle, thereby partitioning it. The partitioning devices described herein both secure to the heart wall (e.g., by anchors, barbs, spikes, etc.) and also (and possibly separately) seal to the heart wall. Sealing to the wall of a heart chamber may be complicated or made difficult by the presence of trabeculations and wall irregularities. Thus, the devices described herein may include one or more sealing elements that are configured to help seal the device (e.g., the partitioning membrane of the device) to the heart wall.

The partitioning devices described herein may also be configured so that the non-productive region formed by the partitioning device may be filled after it is deployed. Filling the non-productive portion may prevent leak, and may also help secure the device in position. As described in detail below, any appropriate filling material may be used, including occlusive material such as coils, fluids (saline, blood, etc.), or the like.

Also described below are variations of partitioning devices that include one or more containers. A container may be referred to as a compartment, chamber, bag, or the like. Partitioning devices including containers may be deployed into the heart (e.g., in the ventricle), so that the container portion is within (or at least partially forms) the non-productive region. In some variations, portions of the partitioning device are contained within the container. The container may be filled or fillable, and may include one or more ports for filing. The ports may be valved, and may include one-way valves so that the container does not leak. Thus, the container may be fluid-tight. The container may be located distally to the pressure-receiving membrane of the device (which may form a portion or wall of the chamber), and may fill all or most of the non-productive space. In some variations the chamber includes anchors (e.g., hooks, barbs, adhesive, etc.) to secure the chamber to the wall of the ventricle. These anchors may be in addition to other anchors or securing elements on the device (e.g., around the perimeter of the pressure-receiving membrane).

For example, FIGS. 1-4 illustrate one variations of a partitioning device 10 which includes a partitioning membrane (e.g., pressure-receiving membrane) 11, a hub 12, preferably centrally located on the partitioning device, and a radially expandable reinforcing frame 13 is secured to the proximal or pressure side of the frame 13 as shown in FIG. 1. The ribs 14 have distal ends 15 which are secured to the hub 12 and free proximal ends 16 which are configured to curve or flare away from a center line axis. Radial expansion of the free proximal ends 16 unfurls the membrane 11 secured to the frame 13 so that the membrane presents a pressure receiving surface 17 which defines in part the productive portion of the patient's partitioned heart chamber. The peripheral edge 18 of the membrane 11 may be serrated as shown.

In this example, the device includes a sealing element that is a continuous expansive strand 19 that extends around the periphery of the membrane 11 on the pressure side thereof to apply pressure to the pressure side of the flexible material of the membrane to effectively seal the periphery of the membrane against the wall of the ventricular chamber. The ends 20 and 21 of the expansive strand 19 are shown extending away from the partitioning device in FIGS. 2 and 3. The ends 20 and 21 may be left unattached or may be secured together, e.g., by a suitable adhesive or the membrane 11 itself. While not shown in detail, the membrane 11 has a proximal layer secured to the proximal faces of the ribs 14 and a distal layer secured to the distal faces of the ribs in a manner described in U.S. patent application Ser. No. 10/913,608, titled “VENTRICULAR PARTITIONING DEVICE,” filed Aug. 5, 2004, now U.S. Patent Publication No. 2006-0030881-A1, now abandoned.

The hub 12 shown in FIGS. 4 and 5 may connect to a non-traumatic support component 22. The support component 22 has a stem 23 a plurality of pods or feet 24 extending radially away from the center line axis and the ends of the feet 24 are secured to struts 25 which extend between adjacent feet. A plane of material (not shown) may extend between adjacent feet 24 in a web-like fashion to provide further support in addition to or in lieu of the struts 25. The inner diameter of the stem 23 is threaded to secure the partitioning device 10 to a delivery catheter as shown in FIGS. 8-10.

In the variation shown in FIG. 5, the distal ends 15 of the ribs 14 are secured within the hub 12 and, as shown in FIG. 6, a transversely disposed connector bar 26 may be secured within the hub which is configured to secure the hub 12 to the atraumatic support component 22.

As illustrated in FIGS. 5 and 6, the connector bar 26 of the hub 12 allows the partitioning device 10 to be secured to the non-traumatic support component 22 and to be released from the delivery system within the patient's heart chamber. The distal ends 15 of the reinforcing ribs 14 are secured within the hub 12 in a suitable manner or they may be secured to the surface defining the inner lumen or they may be disposed within channels or bores in the wall of the hub 12. The distal end of the ribs 14 are pre-shaped so that when the ribs are not constrained, other than by the membrane 11 secured thereto (as shown in FIGS. 1 and 2), the free proximal ends 16 thereof expand to a desired angular displacement away from the centerline axis which is about 20° to about 90°, preferably about 50° to about 80°. The unconstrained diameter of the partitioning device 10 may be greater than the diameter of the heart chamber at the deployed location of the partitioning device so that an outward force is applied to the wall of the heart chamber by the partially expanded ribs 14 during systole and diastole so that the resilient frame 13 augments the heart wall movement.

FIG. 7 illustrates the curved free proximal ends 16 of ribs 14 which are provided with sharp tip elements 27 configured to engage and preferably penetrate into the wall of the heart chamber and hold the partitioning device 10 in a deployed position within the patient's heart chamber so as to partition the ventricular chamber into a productive portion and a non-productive portion.

FIGS. 8-10 illustrate one variations of a delivery system 30 for delivering a partitioning device 10 such as the one shown in FIGS. 1 and 2 into a patient's heart chamber and deploying the partitioning device to partition the heart chamber as shown in FIGS. 11A-11E. This example of a delivery system 30 includes a guide catheter 31 and a delivery catheter 32.

The guide catheter 31 has an inner lumen 33 extending between the proximal end 34 and distal end 35. A hemostatic valve (not shown) may be provided at the proximal end 34 of the guide catheter 31 to seal about the outer shaft 37 of the delivery catheter 32. In this example, the guide catheter includes a flush port 36 on the proximal end 34 of guide catheter 31 that is in fluid communication with the inner lumen 33.

The delivery catheter 32 has an outer shaft 37 with an adapter 38 on the proximal end thereof having a proximal injection port 39 which is in fluid communication with the interior of the shaft 37. As shown in more detail in FIG. 9, the outer shaft 37 has an inner shaft 41 which is disposed within the interior thereof and is secured to the inner surface of the outer shaft 37 by webs 43 which extend along a substantial length of the inner shaft. The injection port 39 is in fluid communication with the passageways 42 between the inner and outer shafts 41 and 37 respectively and defined in part by the webs 42. A torque shaft 44, which is preferably formed of hypotubing (e.g., formed of stainless steel or superelastic NiTi), is disposed within the inner lumen 45 of the inner shaft 41 and has a proximal end 46 secured within the adapter 38. Balloon inflation port 47 is in fluid communication with the inner lumen 48 of the torque shaft 44. In some variations, additional passageways may be present in the delivery catheter. For example, a filling passageway may be included that may be used to fill the non-productive region behind the partitioning device with one or more fillers (e.g., coils, fluids, etc.). In some variations, an additional inflation lumen may be included for inflating a sealing element (e.g., a sealing balloon).

Torque shaft 44 may be rotatably disposed within the inner lumen 45 of the inner shaft 41 and secured to rotating knob 49. A helical coil screw 50 may be secured to the distal end 51 of the torque shaft 44 and rotation of the torque knob 49 on the proximal end 46 of the torque shaft 44 rotates the screw 51 to facilitate deployment of a partitioning device 10. The proximal end 52 of inflatable balloon 53 may be sealingly secured by adhesive 54 about the torque shaft 44 proximal to the distal end 51 of the torque shaft. The balloon 53 may have an interior 55 in fluid communication with the inner lumen 48 of the torque shaft 44. Inflation fluid may be delivered to the balloon interior 55 through port 47 which is in fluid communication with the inner lumen 48 of the torque shaft 44. The distal end 56 of the balloon 53 in this example is sealingly secured by adhesive 57 to the helical screw 50. The proximal and distal ends 52 and 56 of the balloon 53 are blocked by the adhesive masses 54 and 57 to prevent the loss of inflation fluid delivered to the interior 55 of the balloon 53. Delivery of inflation fluid through a fluid discharge port 58 in the distal end 51 of the torque shaft 44 inflates the balloon 53 which in turn applies pressure to the proximal surface of the partitioning device 10 to facilitate securing the partitioning component 10 to the wall 59 of heart chamber 60 as shown in FIGS. 11A-11E discussed below.

In the example shown in FIG. 11A, the partitioning component 10 is delivered through a delivery system 30 which includes a guide catheter 31 and a delivery catheter 32. The partitioning component 10 is collapsed in a first, delivery configuration which has small enough transverse dimensions to be slidably advanced through the inner lumen 33 of the guide catheter 31. Preferably, the guide catheter 31 has been previously percutaneously introduced and advanced through the patient's vasculature, such as the femoral artery, in a conventional manner to the desired heart chamber 60. The delivery catheter 32 with the partitioning component 10 attached is advanced through the inner lumen 33 of the guide catheter 31 until the partitioning component 10 is ready for deployment from the distal end of the guide catheter 31 into the patient's heart chamber 60 to be partitioned.

As shown in FIG. 11B, the partitioning component 10 mounted on the screw 50 is urged further out of the inner lumen 33 of the guide catheter 32 until the support component 22 engages the heart wall 59. The guide catheter 31 is withdrawn while the delivery catheter 32 is held in place until the proximal ends 16 of the ribs 14 exit the distal end 35 of the guide catheter. As shown in FIG. 11C, the free proximal ends 16 of ribs 14 expand outwardly to press the sharp proximal tips 27 of the ribs 14 against and preferably into the tissue lining the heart wall 59.

With the partitioning component 10 deployed within the heart chamber 60 and preferably partially secured therein, inflation fluid is introduced through the inflation port 58 in the distal end 51 torque shaft 44 where it is directed into the balloon interior 54 to inflate the balloon 53. The inflated balloon 53 presses against the pressure receiving surface 17 of the membrane 11 of the partitioning component 10 to ensure that the sharp proximal tips 27 are pressed well into the tissue lining the heart wall 59 as shown in FIG. 11D.

In some variations, the partitioning device may include one or more inflatable elements that may be used to expand the device (or assist with expansion), as describe in greater detail below in reference to FIGS. 30A-30D. Thus, the applicator (e.g., guide and/or delivery catheters) may not include an inflatable balloon 53. Instead, the applicator may include a connector to connect to the inflatable elements on (e.g., the periphery of) the partitioning device.

With the partitioning device 10 properly positioned within the heart chamber 60, the knob 49 on the torque shaft 44 (as shown in FIG. 8) is rotated counter-clockwise to disengage the helical coil screw 50 of the delivery catheter 32 from the stem 23 secured within hub 12. The counter-clockwise rotation of the torque shaft 44 rotates the helical coil screw 50 which rides on the connector bar 26 secured within the hub 12. Once the helical coil screw 50 disengages the connector bar 26, the delivery system 30, including the guide catheter 31 and the delivery catheter 32, may then be removed from the patient.

The proximal end 34 of the guide catheter 31 in this example is provided with a flush port 36 to inject fluids such as therapeutic, diagnostic or other fluids through the inner lumen 33 during the procedure. Similarly, the proximal injection port 39 of adapter 38 is in communication with passageways 43 if the delivery catheter 32 for essentially the same purpose.

The deployment of the partitioning component 10 in the patient's heart chamber 60 as shown in FIG. 11E divides the chamber into a main productive or operational portion 61 and a secondary, essentially non-productive portion 62. The operational portion 61 is smaller than the original heart chamber 60 and provides for an improved ejection fraction and an improvement in blood flow. Over time, the non-productive portion 62 may fill first with thrombus and subsequently with cellular growth. Bio-resorbable fillers such as polylactic acid, polyglycolic acid, polycaprolactone and copolymers and blends may be employed to initially fill the non-productive portion 62. Fillers may be suitably supplied in a suitable solvent such as dimethylsulfoxide (DMSO). Other materials which accelerate tissue growth or thrombus may be deployed in the non-productive portion 62 as well as non-reactive fillers. Fillers may include solid materials or liquid materials, or both, and may include material that expands after being loaded into the non-productive portion or a chamber within the non-productive portion. For example, the filler may be a coil such as a vasoocclusive coil.

As described in greater detail below, the partitioning devices described herein may also be sealed against the wall(s) of the heart, so that the material used to fill does not leak (or does not substantially leak. In some variations a chamber (e.g., bag) may also be part of the partitioning device and may be positioned within the non-productive portion and be filled by the filler.

FIG. 12 is a top view of the deployed partitioning device shown in FIG. 11E schematically illustrating the sealed periphery of the membrane 11 against the ventricular wall. This is to be compared with the schematic presentation shown in FIG. 13 which illustrates a partitioning device without a sealing element such as a strand (or other expandable sealing element) having folds along the periphery 18 which do not allow for an effective seal against the wall 59 of the heart chamber 60. The partitioning device 10 may be conveniently formed by the method described in application Ser. No. 10/913,608, filed Aug. 5, 2004, which is incorporated herein by reference.

While porous ePTFE material is preferred, the membrane 11 may be formed of suitable biocompatible polymeric material which includes Nylon, PET (polyethylene terephthalate) and polyesters such as Hytrel. The membrane 11 may be foraminous in nature to facilitate tissue ingrowth after deployment within the patient's heart. The delivery catheter 32 and the guiding catheter 31 may be formed of suitable high strength polymeric material such as PEEK (polyetheretherketone), polycarbonate, PET, Nylon, and the like. Braided composite shafts may also be employed.

FIGS. 14-16 illustrate the collapse and retrieval of a partitioning device 10 by pulling on the ends 20 and 21 of the expansive strand 19 which extends around the periphery of the membrane 11. Typically, the partitioning device 10 would still be secured to the delivery catheter 32, but the delivery catheter is not shown to simplify the drawings. In FIG. 14 the partitioning device 10 is shown in a partially collapsed configuration. In FIG. 15 the partially collapsed partitioning device 10 is shown being withdrawn into the flared distal end 63 of retrieval catheter 64. FIG. 16 illustrates the completely collapsed partitioning device 10 pulled further into the retrieval catheter 64. The partitioning device 10 may be withdrawn by pulling the device through the inner lumen 65 of the retrieval catheter 64. Optionally, the partitioning device 10 and retrieval catheter may be withdrawn from the patient together.

To assist in properly locating the device during advancement and placement thereof into a patient's heart chamber, parts, e.g. the distal extremity, of one or more of the ribs 14 and/or the hub 12 may be provided with markers at desirable locations that provide enhanced visualization by eye, by ultrasound, by X-ray, or other imaging or visualization means. Radiopaque markers may be made with, for example, stainless steel, platinum, gold, iridium, tantalum, tungsten, silver, rhodium, nickel, bismuth, other radiopaque metals, alloys and oxides of these metals.

FIGS. 17 and 18 illustrate an alternative design which illustrates a partitioning device 10 that includes an expandable sealing element. In this example, the expandable sealing elements are a plurality of swellable bodies 70, preferably hydrophilic foam, around the periphery of the membrane 11 between adjacent ribs 14. When these bodies contact body fluid, such as blood, upon deployment, they swell, thereby sealing the peripheral portion of the membrane 11 against the patient's heart wall as previously described. The details of the partitioning device 10 may be essentially the same as in the previous embodiment and elements in this alternative embodiment are given the same reference numbers as similar elements in the previous embodiments.

To the extent not otherwise described herein, the various components of the partitioning device and delivery system may be formed of conventional materials and in a conventional manner as will be appreciated by those skilled in the art.

FIGS. 19A-19J illustrate application of another variation of a partitioning device 134 being deployed in a human heart 242. The heart 242 contains a right ventricle 244 and a left ventricle 246 with papillary muscles 248 and an akinetic portion 250 with an apex 252. The distal end of the catheter 138 has been inserted through the aorta and aortic valve into the left ventricle 246 to a selected position where the cardiac device 134 can be deployed. The catheter tube 138 is then partially pulled off of the cardiac device 134 exposing the stem 186.

The active anchor 236 is then deployed by rotating the anchor knob 58 in a first direction. The active anchor 236 penetrates the myocardium of the heart 242 to secure the cardiac device 134 in the selected position at the apex 252 of the akinetic portion 250 of the left ventricle 246. In some variations the device does not include an active (e.g., distal) anchor, but may include an atraumatic foot, as described above.

The catheter 138 is then completely removed from the distal end 54 of the deployment member 46, exposing the cardiac device 134. As the cardiac device 134 expands, due to the resilient nature of the segments 192 and the pre-set shape of the frame 184, the passive anchors 214 on the segments 192 penetrate the myocardium in a first direction. The membrane 194 seals a portion of the ventricle 246 and separates the ventricle 246 into two volumes.

If the cardiac device 134 has not been properly positioned, or if it is of the wrong size or shape for the particular heart, the device 134 may be repositioned or completely removed from the heart 242.

FIG. 20A and FIG. 20B illustrate another variation of a cardiac (or partitioning) device 288. This example of a partitioning device 288 includes a sealing element that is configured as a second membrane 300 having fibers (or fringe) 304 that acts to seal against the ventricle wall. The partitioning device 288 in FIGS. 20A-20B includes a first hub 290, a first frame 292, a second hub 294, a second frame 296, a first membrane 298, and a second membrane 300. The first hub 290 is attached to a central portion of the first frame 292. A plurality of segments 302 extend radially from and upwards from the first hub 290. The first membrane 298 is occlusive and made of a thrombogenic material and stretched between the segments 302 to form a first cone-shaped body. A plurality of fibers 304 extend radially from an outer edge 306 of the first cone-shaped body. An active anchor 308 extends down from the first hub 290.

The second frame 296 includes a plurality of segments 310 extending radially and upwardly from the second hub 294 and end in sharp passive anchors 312. An attachment screw 314, similar to the detachment screw 214, extends downwards from the second hub 294. Referring specifically to FIG. 20B, the attachment screw 314 is rotated so that it engages a pin 321 within the first hub 290, similarly to the frame hub 190 already described, to secure the second frame 296 to the first frame 292. The second membrane 300 is made of ePTFE and stretched between the segments 310 to form a second cone-shaped body.

FIG. 20C illustrates a human heart with the partitioning device 288 of FIG. 20A secured to an akinetic portion thereof. The fibers 304 on the outer edge 306 of the first frame 292 are interacting with an inner surface of the left ventricle to seal off the volume below the outer edge 306 of the first frame 292. The passive anchors 312 on the ends of the segments 310 of the second frame 296 have penetrated the myocardium to hold the device 288 in place.

A further advantage of this embodiment is that the fibers 304 of the first membrane 298 interface with trabeculae and further block the flow of blood into the apex of the akinetic portion.

In another variation of the partitioning device described herein, the device includes a plurality of strands extending from the distal side of the device. Thus, the sealing element comprises a plurality of strands or braids that extend from the portion of the device within the non-productive side of the device. These braids may press against an inner surface of the ventricle, and help seal the device within the ventricle.

In some variations the sealing element is an inflatable sealing element. For example, the inflatable sealing element may be a swellable element, as described above in FIGS. 17 and 18, which inflates with fluid to swell. Alternatively, the device may include an inflatable sealing element configured as a balloon, as shown in FIGS. 21A-21C.

FIG. 21A illustrates one variation of a partitioning device in a collapsed or delivery configuration. The device includes a plurality of ribs 2101 to which a membrane 2109 is connected. The ribs connect to a central hub 2111 which connects to an atraumatic foot 2113 in this example. The peripheral region of the membrane includes an inflatable balloon sealing element 2103 having a valve 2105. In FIG. 21A the sealing balloon element 2103 is shown collapsed. The device may be inflated after expanding in the ventricle, or it may be inflated to help expand the device. As mentioned, the delivery catheter may be adapted to communicate with the valve and inflate the device.

Although the valve 2015 for inflation is shown in this example on the periphery of the partitioning device, in some variations, the valve may be located near the center (e.g., radially) of the partitioning device, so that it may be attached to an inflation port on the applicator. In some variations, the partitioning device may include more than one valve.

FIG. 21B shows the partitioning device of FIG. 21C in the (at least partially) expanded configuration, in which the balloon around the periphery of the membrane is inflated. As with the swellable variation of the inflatable sealing element, the balloon may be located at the very periphery of the membrane, or it may be positioned more centrally (e.g., towards the centerline of the device), but still configured to apply pressure to urge the membrane against the wall of the heart and thereby seal the membrane to the wall. FIG. 21C shows a partial cut-away version of the inflatable balloon sealing element, including the passive anchors 2111 at the ends of the implant ribs or struts 2101.

FIGS. 30A-30D illustrate another variation of a partitioning device having an inflatable sealing element. In this example, the inflatable sealing element is a plurality of inflatable elements 3003 that are distributed around the perimeter of the device 3001. As mentioned, inflation of these elements may both expand the partitioning membrane into the deployed form, and may also help seal the membrane against the wall of the ventricle. Thus, the expandable element may provide both circumferential and radial expansion of the partitioning device. For example, FIG. 30A shows a top view of the device indicating the partitioning membrane 3007 (having a peripheral region 3009), and the plurality of expandable and inflatable elements 3003. The inflatable elements may be inflated by one or more inflation channels 3011, which may be connected to a port and/or valve that can be connected to the applicator or other source of inflation material (gas, fluid, etc.).

The inflatable balloon or plurality of balloons at or near the periphery of the membrane of the partitioning device may be formed from the same material as the membrane. For example, the balloon may be integral with the membrane by forming cavities between two layers forming the membrane. For example, the membrane may be formed of two layers of ePTFE sandwiched together. In some variations, the struts or arms are laminated between the two layers. As shown in FIGS. 30A and 30B, a portion of the membrane may be inflatable by preventing them from sealing (laminating) together.

The inflatable element(s) may be connected via an inflation channel 3011 or a plurality of inflation channels 3011, as shown in FIG. 30A, to a port or valve. As mentioned, the valve may be located in any appropriate location so that it may couple with an inflation source. For example, a valve may be positioned in the hub (center) region that typically mates with the applicator. One or more inflation channels (or inflation ports) may be used. For example, in FIG. 30A, the device includes a plurality of inflation channels distributing inflation material to all of the inflatable balloon elements. When a plurality of inflatable balloon elements are used, the device, each inflatable balloon element may be separately inflatable, or all (or a subset) of the inflatable elements may be connected together so as to inflate together.

As mentioned above, any appropriate inflation material may be used, including liquids (e.g., saline), gases, solids, gels, etc. In some variations, the inflatable element(s) described herein may be filled with a contrast agent that may help visualize the partitioning device. For example, the inflatable elements may be filled with a radioopaque contrast media that allows visualization of the partitioning device after it has been deployed in the left ventricle. In some variations, such as the partitioning device shown in FIG. 30B, the periphery of the membrane may be visualized by inflating with a contrast material 3031.

In some variations, the inflation material is a polymerizable or curable. For example, the inflatable elements (e.g., balloon elements) may be inflated with a curable material including a UV curable material or an RF curable material. For example, the filling material may include a UV-curable filling material. Thus, an applicator may also include a light-emitting element such as a fiber optic cable and/or a port for an energy source that can apply the energy (light, heat, etc.) to cure or otherwise modify the material in the inflatable element.

In some variations, the partitioning device may include channels or pathways that may be inflated with a curable material to form one or more of the struts. For example, in FIG. 30A, channels 3011 may be formed within the membrane 3007 either for filing the inflatable elements 3003, or simply to form inflatable struts. These inflatable struts may be filled with a curable material, as mentioned above, which may provide additional structural support. For example, when the membrane is formed by lamination or otherwise securing two or more layers, the struts or other inflatable members may be formed between them (e.g., in non-adhesive regions). Alternatively, inflatable regions may be attached to the membrane(s). In some variations, the partitioning device may therefore include one or more inflatable struts that are formed in vivo, for example, using an elastomeric (e.g., RTV-like) curable material. In some variations the inflatable struts extend radially (e.g., from a common hub region), towards to the distal end of the membrane. The inflatable struts may communicate with inflatable members including inflatable balloon members 3003, as shown in FIG. 30A, or they may not communicate with other inflatable regions, but may terminate or include one or more ports.

The inflatable balloon element(s) may be located at or near the peripheral edge of the device. For example, in FIG. 30A, the inflatable balloon elements are located just proximal to the peripheral edge of the device, so that a portion of the membrane extends distally past the inflatable element. This edge portion may be loose, serrated, (or may form a plurality of flaps), and may help seal the device to the wall of the ventricle. In some variations, the inflatable element is at the periphery of the partitioning device.

FIG. 30B illustrates a side view of the partitioning device of FIG. 30A, showing the inflatable balloon elements near the proximal edge of the membrane.

In use, the inflatable balloon elements may be expanded to open the partitioning device. For example, upon inflation, the inflatable elements may push the expansion of the struts of the device, thereby encouraging radial expansion of the membrane. The inflatable balloon elements may also be configured to accommodate non-circular deployment within the ventricle. FIGS. 30C and 30D illustrate different variations of partitioning devices including inflatable balloon elements that may conform to non-circular (or otherwise irregular) walls of the heart. For example, in FIG. 30C, the plurality of inflatable elements shown 3003 may be inflated so that they provide outward (axially) force to expand the device, and also to seal the device against the ventricle wall, but the plurality of inflatable elements also accommodate irregularities because the size of the sub-regions that include an inflatable balloon element may be displaced without disrupting the rest of the membrane. In FIG. 30C, one region of the partitioning device 3023 is allowed to follow a contour of the heart wall that is not round. For example, where trabeculations or other projections in the ventricle wall make it irregular. Similarly, when the body region (e.g., ventricle) is not rounded but is oval or otherwise non-circular, the inflatable balloon elements as shown in FIG. 30D may allow it to conform to the walls.

In some variations, an inflatable balloon may be included in the partitioning device that is not located on or near the periphery of the membrane. For example, FIGS. 31A and 31B illustrate one variation in which the central region of the implant (e.g., near the hub) on the membrane is inflatable, and inflation may help rapidly expand the partitioning device.

For example, in FIG. 31A, the partitioning device 3101 includes one or more inflatable regions 3103 that are located on the membrane 3107. These inflatable region or regions may also be formed between two of the layers forming the membrane, as mentioned above. For example, two layers of ePTFE forming the membrane may be sealed near the outer periphery 3109 of the device, but allowed to be separate closer to the hub, so that this region may be inflated. A port or ports for inflation (including or more valves) may also be included. In addition to the inflatable elements shown in FIG. 31A, other variations may also include one or more other sealing elements (e.g., a strand, a peripheral inflatable element, etc.) for helping to secure the membrane to the ventricle walls. In some variations the edges of the membrane may also be loose, serrated, etc., so as to help form a seal.

The partitioning device of FIG. 30A is shown in partially transparent side-view in FIG. 30B. In this example, the inflatable elements 3103 (which may also be referred to as inflatable expanding elements or inflatable expanding balloon elements) are indicated. Although these elements may drive the membrane open and towards the wall of the ventricle, they are not necessarily sealing elements, since they do not necessarily tension the membrane (e.g., removing wrinkles) to seal, in contrast to the device shown in FIG. 30A-30D. They may be used in combination with other sealing elements, as mentioned.

FIGS. 22A-25B illustrate variations of the devices including a container surrounding a portion of the partitioning device, and configured to be positioned within the non-productive portion of the heart chamber when the device is deployed in a heart chamber. For example, FIG. 22A shows a cross-section through one variation of a partitioning device in which the implant includes a frame of ribs or struts 2203 and a membrane connected to the frame 2205. One or more passive anchors (e.g., prongs, hooks, etc.) 2213 may be located on the ends of each strut. In this example, the membrane is formed of ePTE, and may be laminated over the frame to form the pressure-receiving surface of the device. The implant also includes a foot 2207 that is relatively soft (e.g., atraumatic) so that it doesn't penetrate the tissue wall, even when the wall may be weakened or akinetic. In this example, the device also includes a container 2232 formed by the pressure-receiving membrane and a second membrane (e.g., an ePTFE membrane) extending distally around the portion of the device that will be positioned within the non-productive portion of the membrane, as illustrated in FIG. 22b . In FIGS. 22A and 22B the container is configured as a bag, the top of which is sealed by the pressure-receiving membrane 2205. The device may include one or more ports 2209 (which may include valves) for filling the container. In FIG. 22A, the ports are configured as skives 2209 through which material may be injected to fill the container. FIG. 22B illustrates the device of FIG. 22A implanted into a ventricle (a left ventricle 2221). In this example, saline 2223 has been injected to fill the container, which contacts the wall of the apex region 2225 of the left ventricle 2221.

FIGS. 23A and 23B show perspective views of a similar variation.

FIG. 24A is another example of a portioning device that includes an occlusive membrane 2403 secured to a plurality of ribs or struts 2405. The device also includes a container 2432 which, similar to the variation shown in FIGS. 22A-23B, is an inflatable bag-like structure formed of ePTFE. The example shown in FIG. 24A also includes a valve, configured as a flap valve, 2435, which is a membrane of ePTFE that covers openings (e.g., skives) through which the container may be filled. The membrane may be biased (e.g., by the elastic structure of the valve, and/or by pressure from within the container) so that it opens for filling, but does not permit a significant amount of material to leave the container. Thus the container may be filled through the implant hub 2409. For example, the container may be filled using the delivery catheter (not shown). The hub portion 2409 and an atraumatic foot region 2401 are shown positioned within the container. In some variations, the container may surround the foot region and/or the hub, but not enclose them.

FIG. 24B shows a top view of the device of FIG. 24A, illustrating the openings 2409 (skives) into the container that are selectively covered by the flap valve 2435. These openings may also be configured so that fluid, such as blood from within the ventricle, can be loaded into the chamber once it is positioned. An example of this is shown in FIGS. 25A (valve open) and 25B (valve closed). In this example, the device is shown expanded within a ventricle 2500. The flap valve allows blood (e.g., blood being pumped through the ventricle) to enter the container 2432, as indicated by the arrows 2439. This may inflate the container within the ventricle, so that the walls of the container conform to the wall of the non-productive region of the ventricle, i.e., the region behind the partitioning membrane 2403 and ribs 2405. For example, during the period of contraction of the ventricle when blood is pushed against the pressure-receiving membrane of the device as the ventricle fills (e.g., diastole), blood may enter and fill the chamber. When the ventricle contracts (e.g., systole), blood is held in the chamber since the flap valve is configured to prevent blood from leaving the chamber. After the chamber is filled, blood may be held within the chamber and prevented from exiting the chamber by the flap valve, as indicated by the arrows 2439′ in FIG. 25B. Thus, this variation may be self-filling.

FIG. 26 illustrates one variation of an applicator that may be used with a partitioning device such as the partitioning devices including chambers illustrated above. In FIG. 26, the applicator is a delivery catheter 2603 that may be used with a guide catheter 2601. The guide catheter 2601 in this example has an inner lumen extending between the proximal end 2604 and distal end. A hemostatic valve (not shown) may be provided at the proximal end 2604 of the guide catheter 2601 to seal about the outer shaft of the delivery catheter 2602. In this example, the guide catheter also includes a flush port 2606 on the proximal end 2604 of guide catheter 2601 that is in fluid communication with the inner lumen.

The applicator delivery catheter 2603 (“applicator”) has an elongated outer shaft 2612 with an inflation port (e.g., deployment inflation port 2615) near the proximal end. The inflation port may be used to inflate an inflatable member on the distal portion of the elongate shaft configured to help expand the device. This inflatable member may also be referred to as a deployment balloon 2655. The deployment inflation port is in communication with an inner lumen in the delivery catheter and with a deployment balloon 2655.

The applicator also includes a releasable securing element as previously described, for releasably securing the implant device. For example, the releasable securing element may include a torque shaft and helical coil screw as illustrated and described in FIG. 8, above.

The applicator may also include a filling interface 2621 near the distal end of the elongate shaft for filling the non-productive portion of the heart formed by the implant. In some variations, the filling interface may be configured as an inflation port for inflating or filling a container portion of the implant. The filling interface may be configured as a filling port, and may be used to fill the non-productive region after the implant has been deployed even if the implant does not include a container portion.

The system shown in FIG. 26 (including a delivery catheter or applicator 2603, insertion catheter 2601, and expandable partitioning device 2605) may also be configured for use with a UV-curable filling material. In this variation, the applicator also includes a light-emitting element such as a fiber optic cable 2633 near the distal end, and a port 2623 for an energy source near the proximal end, so that energy (e.g., UV-light) can be used to cure the filler in the non-productive region and/or the container 2605.

The applicator may also include a handle 2621 at or near the proximal end.

FIG. 27 illustrates another variation of a system including a partitioning device 2705, and an applicator that is configured to deploy a partitioning device and then deliver occlusive members (e.g., coils) into the non-productive portion formed behind the device. For example, in this variation the applicator 2700 includes a control handle 2701 and a balloon deployment inflation port 2709 at the proximal end, as well as an implant detachment knob 2711. Turning the implant detachment knob may rotate the torque shaft (not visible) and deploy the implant, as previously described. The system may also include a delivery catheter 2703.

In FIG. 27, the partitioning device 2705 is shown deployed within the apical region of a left ventricle 2715 so that the foot 2717 of the device rests against the wall and the pressure-receiving membrane forms a non-productive region 2719 separate from the productive region of the ventricle 2716. The membrane may be reinforced with ribs or struts, and may be anchored via one or more securing elements (not visible in this example).

In this variation, the applicator may also be used to apply occlusive elements into the non-productive region 2719. As illustrated the occlusive elements are coils, e.g., thrombogenic coils 2733). Thus, the applicator may include a port and passageway for the occlusive member. For example, the applicator may include a coil delivery catheter 2755, and may also include a coil detachment knob 2757. In operation, the coils may be delivered behind the expanded implant by pushing the coils out of the distal end from behind the deployed partitioning device until this region is filled as desired. The coil may then be detached, although multiple small coils may also be used. Any occlusive material may be used, including any variation of occlusive coil. For example, thrombogenic coils may be used in the non-productive portion.

FIG. 28 illustrates another variation of a partitioning device that can be filled with an occlusive material such as a thrombogenic coil. In this variation the non-productive portion is filled after the device has been deployed using a separate coil delivery device 2805. The coil delivery device (e.g., coil delivery catheter) may be used with the same guide catheter 2703 used to by the applicator to position and deploy the implant. The coil delivery catheter may be used to fill the region behind the device by filling from an edge of the device, by separating the edge of the membrane of the device from the wall of the heart to allow the distal end of the coil delivery device into the non-productive space.

FIGS. 29A-29C illustrate another variation of the method of filling a portion of the non-productive region formed by a partitioning device 2901 with an occlusive material(s) such as occlusive coils. FIG. 29A illustrates one variation of a partitioning device 2901 that includes a container 2903 configured as a pouch or bag that is bounded on at least one side by the pressure receiving membrane 2905. The pressure-receiving membrane 2905 may be supported by struts 2907. In some variations, the container is not bounded by the pressure-receiving membrane. The implant foot 2912 is within the container (which may also be referred to as a bag or pouch).

In operation, the device may be deployed in a heart chamber (e.g., the left ventricle 2950) and the container may be filled with occlusive material. For example, FIG. 29B illustrates the partitioning device of FIG. 29A filled with occlusive coils 2915. When the device is secured within the heart, as illustrated in FIG. 29C, the container may be filled so that virtually the entire non-productive portion is filled (by the filled container).

Turning to FIGS. 32A-32D, described herein are methods of treating a patient to prevent or correct cardiac remodeling following myocardial infarction. In general these methods may include inserting or implanting a device in a heart chamber within 72 hours after myocardial infarction, or shortly after a determination of myocardial infarction. The device is preferably placed within the region of the heart chamber exhibiting one or more indication of myocardial infarction. The device may be a support device (e.g., a resilient frame) and/or a partitioning device.

For example, FIG. 32A is a schematic illustration of a patient's heart 3210 showing the right ventricle 3211 and the left ventricle 3212 with the mitral valve 3213 and aortic valve 3214. A pericardium membrane 3215 is shown surrounding the heart 3210. At least a portion of myocardium layer 3217 of the left ventricle 3212, as shown in FIG. 32A, is exhibiting an area of infarct 3218 (“MI”) extending along a portion of ventricular septum wall 3219 which separates the right and left ventricles. This region may exhibit characteristics of an incipient rupture. FIG. 32B illustrates the advancing of the infarct leading to the generation of a rupture or opening 3220 in the septum wall 3219, a condition referred to as VSD. As shown in FIG. 32B oxygenated blood 3221 flows directly to the right ventricle 3211 through the septum opening 3220. As a result of this movement, or shunting, at least two consequences are reached, firstly, the right portion of the heart works harder pumping a greater volume of blood than it normally would, and secondly, the amount of oxygenated blood in the left ventricle is reduced leading to a lower oxygen level to the other tissues of the body.

In some variations, the heart may be treated after the development of the rupture, as illustrated in FIG. 32C. FIG. 32C illustrates the left ventricle 3212 of FIG. 32B after it has been partitioned, with the use of a partitioning device 3230 according to the present invention and as described further below, into a main productive or operational portion 3223 and a secondary, essentially non-productive portion 3224. As can be seen from FIG. 32C, with fluid path to the septum opening blocked or reduced, the normal flow of blood from the left ventricle to the rest of the body through the aortic valve is restored.

In some variations, it may be preferable to treat the heart following myocardial infarction prior to remodeling such as the formation of the rupture shown in FIGS. 32B and 32C. For example, FIG. 32D shows the schematic illustration of the heart of FIG. 32A shortly after determination of a myocardial infarction. The region of the heart chamber exhibiting myocardial infarction (the area of infarct 3218) is indicated, and in this example a device 3230 has been deployed to reinforce this region. As a part of the method, the device is deployed into the heart chamber adjacent to the region of the heart chamber exhibiting myocardial infarction shortly after a determination of the myocardial infarction has been made. Generally, this occurs prior to substantial remodeling of the heart. For example, this may be less than 72 hours after the myocardial infarction, or less than a few days after the determination of a myocardial infarction.

The occurrence of a myocardial infarction may be determined by any appropriate method, including diagnostics based on physical examination, electrocardiogram, blood (or other tests) for cardiac markers, angiograms, or the like. For example, enzyme markers (e.g., SGOT, LDH, creatine kinase), or other markers (e.g., troponins, glycogen phoshyorylase isoenzyme, myoglobin, etc.) may help determine myocardial infarction. The region of the heart affected by the myocardial infarction may also be determined. For example, visualization techniques (direct or indirect) may be used. For example, angiograms may be used. Other visualization techniques, including scanning (e.g., echocardiography, CT scanning, etc.), electrical mapping, etc. may also be used to localize an area of infarct.

FIG. 33A is a schematic illustration of a patient's heart 3210 showing the right ventricle 3211 and the left ventricle 3212 with the mitral valve 3213 and aortic valve 3214. The pericardium membrane 3215 is shown surrounding the heart. A pericardium (pericardial complex) consists of an outer fibrous layer and an inner serous layer. The pericardial space 3216 normally contains 20-50 mL of fluid. At least a portion of the myocardium layer 3217 of the left ventricle 3212, as shown in FIG. 33A, is exhibiting an area of infarct 18 (“MI”) extending along a portion of the left ventricle 3212, which may result in a wall rupture or opening leading to a movement of blood 3221 from the left ventricle into the pericardial space 3216, as illustrated in FIG. 33B.

FIG. 33B shows the remodeling of the heart following MI. In FIG. 33A the damage from the infarct has advanced, leading to the rupture or opening 3220 which is increasing in size. As shown in FIG. 33B, the flow of the blood 3221 into the pericardial space 3216 increases over time leading to a greater accumulation of blood in the pericardial space. This movement and accumulation of blood in the pericardial space, a condition referred to as ventricular tamponade, results in reduced ventricular filling and subsequent hemodynamic compromise.

This damage may be prevented or reversed by implanting or inserting a support and/or partitioning device, as shown in FIG. 33C. FIG. 33C illustrates the left ventricle 3212 of FIG. 33A after a device 3230 has been inserted. This device 3230 is a partitioning device which both supports the damaged area, and may partition it from other portions of the heart chamber, into the main productive or operational portion 3223 and the secondary, essentially non-productive portion 3224. As can be seen from 32D and 33C, supporting the damaged region of the heart chamber (e.g., the area of infarct 3218), and in some variations partitioning it, may prevent or reverse the remodeling of the heart and help restore the normal flow of blood from the left ventricle to the rest of the body through the aortic valve.

FIG. 34 illustrates an alternative design which embodies features of a device usable in practicing methods having features of the present invention, in which the device 3230′ is provided with an eccentric-shaped membrane 3231 which is well suited for treating VSD lesions that may occur further up (more proximal) the ventricular septum because of the different anatomical features and physiologic action of the ventricular septum versus the anterior free wall. The septal wall primarily moves in and out only, relative to the chamber, versus the free wall that has a rotation component to its excursion. Secondly, the outflow track which comprises the upper half of the ventricular septal wall below the aortic valve has very little or no trabeculation. It is particularly well suited for placement of the device placed to address necrotic failure of the tissue of the ventricular septum. In the embodiment shown in FIG. 34, the device is shown with a nubbin foot 3245 (and not the extended stem foot) allowing the device to sit more distally and intimately with the apex.

The details of the device 3230′ shown in FIG. 34 are essentially the same as in the previous embodiments and elements in this alternative embodiment are given the same reference numbers but primed as similar elements in the previously discussed embodiments. The device 3230′ forms a conical shape as in the previously discussed embodiments but the peripheral base of the conical shape which engages the wall that has a first dimension in a first direction greater than a second dimension in a second direction. Preferably, the second direction is at a right angle with respect to the first direction. The lengths of the ribs 3234 are adjusted to provide the desired shape to the periphery of the device which engages the interior of the heart chamber.

Any of the devices described herein (e.g., the devices 3230, 3231′) may be conveniently formed by the method described in application Ser. No. 10/913,608, which is incorporated herein by reference in its entirety.

In variations having a membrane, porous ePTFE materials may be preferred. Alternatively, the membrane 31 may be formed of suitable biocompatible polymeric material which includes Nylon, PET (polyethylene terephthalate) and polyesters such as Hytrel. The membrane 31 is preferably foraminous in nature to facilitate tissue ingrowth after deployment within the patient's heart. The delivery catheter 52 and the guiding catheter 51 may be formed of suitable high strength polymeric material such as PEEK (polyetheretherketone), polycarbonate, PET, Nylon, and the like. Braided composite shafts may also be employed.

FIGS. 35A through 36B illustrate other variations of devices and methods for using them to prevent remodeling. FIG. 35A shows a device that does not include an occlusive membrane. In this variation of a support device, a plurality of struts 1501 extend from a central hub 1503. The ends of each strut 1501 terminate in an anchor 1505. The struts are typically flexible, and may be collapsed into a delivery configuration and expanded (e.g., self-expanded) into a deployed configuration. The support device shown in FIG. 35B is similar, but has struts of different lengths, similar to the device shown in FIG. 34. FIG. 35C shows a schematic illustration of a heart in which the support device 1506 of FIG. 35A has been implanted adjacent a region of the chamber wall exhibiting myocardial infarction (post-MI infarct 1507). In some variations, the devices 1506 may be anchored along the length of the struts rather than, or instead of, just at the ends. In some variations the hub is anchored to the heart chamber wall.

FIG. 36A shows another variation of an implant 1600, similar to the implant shown in FIG. 1, without the plurality of pods or foot 45. In this example, the hub 1603 may directly contact the wall of the heart chamber. In some embodiments, the implant 1600 further includes one or more struts 1601, an occlusive membrane 1602, and one or more passive anchors 1605 (e.g., on the tip of the one or more struts). FIG. 36B shows the device of FIG. 36A in the heart. For example, the implant 1600 may be positioned in the left ventricle 1610, proximal to the papillary muscle 1612, and adjacent to the infarcted region 1614 of the heart.

As mentioned, the implant devices used to treat post-acute myocardial infracted hearts may be configured so that the support framework (e.g., struts) and/or any membrane may be positioned adjacent, contacting, or very close to the wall of the heart. For example, FIGS. 39A and 39B show cross-sectional views of two hearts that have devices 1901, 1901′ implanted adjacent to the wall in the region affected by the acute myocardial infarction 1903, 1903′.

FIGS. 37A and 37B illustrate another variation of a device that may be implanted following acute myocardial infarction in order to prevent cardiac remodeling or damage (configured as an endocardial implant). In this example, the device is configured to be anchored immediately adjacent to the heart wall (e.g., ventricle wall) across from the region of the infarct. The implant 3700 includes a frame 3702 comprising a plurality of expandable struts which extend from a central hub. The base of the hub in this example includes an anchor 3704 (“active anchor”) which may be inserted into the heart wall. For example, the hub anchor may 3704 be screwed into the heart wall by rotating the device to at least partially penetrate the heart wall and secure the device in place. In addition, the device may also include one or more passive anchors 3706 on the struts of the frame 3702, as illustrated. In this variation the struts are at least partially covered by a membrane 3708. The implant shown in FIG. 37A is shown in side cross-section in FIG. 37B.

FIG. 37C illustrates one variation of a delivery system including a delivery catheter 3710 and guide catheter 3712 for delivering the implant to the heart so that it can be deployed and inserted. For example, the delivery device shown in FIG. 37C includes a delivery catheter 3710 having an implant 3700 (shown in the collapsed state) at the distal end. FIG. 37D shows the delivery system inserting the implant 3700 into the left ventricle 3710 of a heart.

To the extent not otherwise described herein, the various components of the devices and delivery systems may be formed of conventional materials and in a conventional manner as will be appreciated by those skilled in the art.

Cardiac endothelium plays an important role in control of the inflammatory response of the myocardium, growth of the heart muscle cells, contractile performance and rhythmicity of the cardiomyocytes. Cardiac endothelial dysfunction has also important role in the pathogenesis of cardiac failure. Therefore, it may be advantageous to selectively deliver therapeutic agents and/or cells to the endothelium in controlled and predictable fashion. The devices (e.g., support device and partitioning devices) described herein may be used to treat disorders by delivering a therapeutic material, including drugs and cells. For example, a frame of a device and/or the membrane of a device can be coated and/or impregnated with a biodegradable coating containing therapeutic agents and deliver these agents to the endothelium. Similarly, a delivery catheter can provide access to infuse various solutions of the therapeutic agents or cells to the area between the devices (e.g., a membrane of the device) and the endothelium, providing precise control of the delivery process to facilitate healing and local regeneration. Any appropriate therapeutic agents may be used, including cytokines, chemokines, inflammatory mediators, growth factors, inotropic agents, anti-arrhythmic agents, other pharmaceutical agents commonly used for treatment post-infarction condition, and various types of cells (myocytes, myoblasts, stem cells).

While particular forms of the invention have been illustrated and described herein, it will be apparent that various modifications and improvements can be made to the invention. Moreover, individual features of embodiments of the invention may be shown in some drawings and not in others, but those skilled in the art will recognize that individual features of one embodiment of the invention can be combined with any or all the features of another embodiment. Accordingly, it is not intended that the invention be limited to the specific embodiments illustrated. It is intended that this invention to be defined by the scope of the appended claims as broadly as the prior art will permit.

As used herein, terms such a “element,” “member,” “component,” “device,” “section,” “portion,” “step,” “means” and words of similar import, shall not be construed as invoking the provisions of 35 U.S.C. § 112(6) unless the following claims expressly use the term “means” followed by a particular function without specific structure or the term “step” followed by a particular function without specific action. Accordingly, it is not intended that the invention be limited, except as by the appended claims. All patents and patent applications referred to herein are hereby incorporated by reference in their entirety. 

What is claimed is:
 1. A ventricular partitioning device comprising: a membrane disposed around a center region; a valve positioned in the center region; and an inflation channel radially extending from the valve to a peripheral region of the membrane, wherein the inflation channel is in fluid communication with the valve, wherein the valve is configured to control passage of a fluid into the inflation channel, wherein the membrane is outwardly expandable when the fluid passes into the inflation channel, and wherein the device further comprises an inflatable element positioned on or in the peripheral region of the membrane, wherein the inflatable element is in fluid communication with the inflation channel and the valve.
 2. The ventricular partitioning device of claim 1, wherein the membrane comprises two layers.
 3. The ventricular partitioning device of claim 2, wherein the inflatable element is defined by a cavity between the two layers forming the membrane.
 4. The ventricular partitioning device of claim 2, wherein the inflation channel is formed by an unsealed channel between the two layers forming the membrane.
 5. The ventricular partitioning device of claim 1, wherein the membrane comprises ePTFE.
 6. The ventricular partitioning device of claim 1, wherein the inflation channel comprises a plurality of inflation channels.
 7. The ventricular partitioning device of claim 6, wherein one or a subset of the plurality of inflation channels are configured to inflate when fluid passes through the valve.
 8. The ventricular partitioning device of claim 1, wherein the inflatable element comprises a plurality of inflatable elements.
 9. The ventricular partitioning device of claim 8, wherein one or a subset of the plurality of inflatable elements are configured to inflate when fluid passes through the valve.
 10. The ventricular partitioning device of claim 1, wherein the ventricle partitioning device circumferentially expands when fluid passes into the inflatable element.
 11. The ventricular partitioning device of claim 1, wherein the partitioning device radially expands when fluid passes into the inflation channel.
 12. The ventricular partitioning device of claim 1, wherein the fluid comprises a gas or liquid.
 13. The ventricular partitioning device of claim 1, further comprising a plurality of struts coupled to the membrane.
 14. The ventricular partitioning device of claim 13, wherein each of the plurality of struts comprises an anchor configured to secure to a wall of the ventricle.
 15. The ventricular partitioning device of claim 1, wherein the valve is connectable to an applicator, and wherein the applicator is configured to provide fluid to the valve.
 16. The ventricular partitioning device of claim 1, wherein the inflatable element conforms to a surface of a wall of a ventricle when inflated within the ventricle.
 17. The ventricular partitioning device of claim 1, wherein the partitioning device is non-circular when expanded in a ventricle.
 18. A device as claimed in claim 1, wherein the inflatable element is located just proximal to a peripheral edge of the device, so that a portion of the membrane extends distally past the inflatable element.
 19. A device as claimed in claim 18, wherein the portion of the membrane that extends distally past the inflatable element is loose and is adapted to help seal the device to a wall of the ventricle.
 20. A ventricular partitioning device comprising: a membrane disposed around a center region; a valve disposed in a portion of the ventricular partitioning device; and an inflation channel radially extending from the valve to a peripheral region of the membrane, wherein the inflation channel is in fluid communication with the valve, wherein the valve is configured to control passage of a fluid into the inflation channel, wherein the membrane is outwardly expandable when the fluid passes into the inflation channel; and wherein the membrane comprises two layers.
 21. A device as claimed in claim 20, wherein the device further comprises an inflatable element positioned on or in the peripheral region of the membrane, wherein the inflatable element is in fluid communication with the inflation channel and the valve. 